FR2977912A1 - EXHAUST GAS POST-TREATMENT ASSEMBLY OF A COMBUSTION ENGINE COMPRISING AN IMPACT-REDUCING AGENT DISTRIBUTOR - Google Patents

Abstract

The invention relates to an aftertreatment assembly for the exhaust gas of a combustion engine, comprising, according to the direction of flow of the exhaust gas, a catalyst for selective catalytic reduction of the nitrogen oxides (4). ) disposed in an envelope bent downstream of a bend of the casing, the assembly further comprising a reducing agent injector (5) for the selective catalytic reduction of the nitrogen oxides, arranged so as to inject the reducer into the elbow, characterized in that it further comprises one or more impactors (7) arranged to be impacted by all or part of the injected reducer so as to distribute it over the entire output section of the elbow (31). The invention also relates to a motor vehicle having a front under-bonnet space in which is disposed a combustion engine and such an assembly.

Description

The invention relates to the field of exhaust gas pollution control means for a combustion engine. The invention relates to the field of exhaust gas pollution control means of a combustion engine. combustion. Polluting emissions of combustion engines fitted to motor vehicles are regulated by increasingly stringent standards. Regulated pollutants are carbon monoxide (CO), unburned hydrocarbons (HC), nitrogen oxides (NOx), and particulates, depending on the combustion engine technology considered. It is known to employ a number of pollution control means in the exhaust line of combustion engines to limit the emissions of regulated pollutants. An oxidation catalyst allows the treatment of carbon monoxide, unburned hydrocarbons, and under certain conditions nitrogen oxides; a particulate filter can be used for the treatment of soot particles. These devices are generally designated by the term "after-treatment" means of the exhaust gases. For example, to meet pollution control standards on nitrogen oxide (NOX) emissions, a specific post-treatment system can be introduced into the exhaust line of vehicles, including vehicles equipped with lean-burn engines, ie of the diesel or spark-ignition type operating with a stratified mixture (non-homogeneous fuel mixture having a fuel content lower than the stoichiometry). For the treatment of nitrogen oxides (NOX), selective catalytic reduction ("SCR") technologies are known which consist in reducing NOX by introducing a reducing agent (or a precursor of such a reducing agent) in the exhaust gas. It may for example be a urea solution, the decomposition of which will make it possible to obtain ammonia which will serve as a reducing agent, but also of a reducing agent or a precursor of such a reducing agent. gaseous form. In the remainder of the present document, a "reducing agent" will generally be used to designate a reducing agent or a reducing agent precursor. Conventionally, the SCR catalyst is placed under the vehicle body, away from the engine because the injected reducer requires a long route in the exhaust line to decompose on the one hand, and free volumes sufficient to be implanted d 'somewhere else. If the distance traveled by the reducer is not sufficient the risk of clogging of the exhaust line is important. However, if it is placed far from the outlet of the exhaust manifold of the engine, or the outlet of the turbine in the case of a supercharged engine, the catalyst SCR may not be active from the first seconds. of operation of the vehicle, and then let pass a large amount of untreated nitrogen oxides. Similarly, the gearbox injector, which requires reaching a certain temperature level to be operational (sufficient initiation of the decomposition of the urea precursor (adblue) or preheating of the reducer delivery system (gas)) , suffers from this distance from the outlet of the exhaust manifold. It is known from the French patent application filed in the name of the applicant under the number FR 11 51374 (not published today) a system grouping the same elements of pollution in a U compact architecture. Such devices can be fully implanted under the bonnet of a motor vehicle. More generally, an angled device may allow implantation under the hood, depending on the application in question. The adoption of such a post-processing device offers, in addition to the performance advantages of the post-processing means, advantages in terms of implementation of the systems in the vehicle, allowing the removal of all means of post-treatment of the subfloor area of the vehicle. It is necessary in any SCR system to ensure a good mixture of the reducer in the exhaust gas prior to its arrival on the SCR catalyst. It is known to use to promote this mixture a device called mixer, interposed between the reducer injection point and the catalyst SCR, which aims to create turbulence in the exhaust gas. There are many types of mixers suitable for this purpose. The mixers are optimized to reduce as much as possible the length of the exhaust line necessary to obtain a good homogeneity of the mixture reducer / exhaust gas. For example, document FR2947003 discloses a high-performance mixer for ensuring homogeneous mixing over a linear length of very short exhaust line. However, the mixers are often complex devices, and adapted to an exhaust line in which the different depollution devices are arranged one after the other, in a conventional longitudinal arrangement. Most known mixers are cylindrical and must be arranged in a cylindrical envelope or "canning". These devices are not suitable for a compact U-shaped architecture or more generally with an envelope or "canning" bent (for example an architecture of canning L), because the mixture can not be performed by a traditional mixer in non-straight and / or non-cylindrical parts. In addition, these devices generate significant pressure drops, which penalize the performance of the engine equipped. However, document WO10053033 discloses mixing means adapted to a configuration in which the exhaust gases, in which the gearbox has been introduced beforehand, are introduced into an envelope containing a SCR catalyst positioned at 90 ° from the direction introduction of gases. However, the system requires the preintroduction of the reducer in the gases, before entering the canning, and on the other hand is not adapted to a canning architecture in U or L, but to an architecture having a duct d 90 ° exhaust in a canning, for expelling the exhaust gases on a wall of the canning having a particular geometry generating a reflux in the opposite direction of the gas introduction direction. In order to overcome these problems, the applicant has filed under FR1152142 a patent application (unpublished to date) in which is described a set of bending treatment, typically having a geometry in "U" or " L "having an envelope with a boss forming SCR gearbox mixer. If this request presents simple and effective means of obtaining a homogeneous mixture between the exhaust gas and the SCR gearbox, the efficiency of the means involved is dependent on the dynamics of the exhaust gas in the exhaust gas. set of post-processing. The object of the invention is to propose means for ensuring a homogeneous distribution of a fluid introduced into the exhaust gas of a combustion engine, as part of an architecture of a device. compact exhaust gas aftertreatment system having a single, bent, "U" or "L" -shaped envelope (canning), taking advantage of this configuration and the dynamics of the gearbox injection to guarantee this distribution efficiently and independently of the operating conditions of the engine (and thus the flow of exhaust gas in the post-treatment assembly), while limiting the pressure losses generated. More specifically, the invention therefore relates to a set of aftertreatment of the exhaust gas of a combustion engine, comprising, according to the flow direction of the exhaust gas, a catalytic selective reduction catalyst nitrogen oxides disposed in an angled envelope, downstream of a bend of the casing, the assembly further comprising a reducing injector for the selective catalytic reduction of the nitrogen oxides, arranged so as to inject the reductant in the bend, and further comprising one or more impactors arranged to be impacted by all or part of the injected reducer so as to distribute it over the entire exit section of the bend. This avoids obtaining a poor distribution of the reducer in the flow of the exhaust gas, and in particular obtaining a high concentration of reducer in an area opposite the injector (because an injector jet tends to focus at a defined distance from the injection point).

Preferably, the assembly comprises several impactors which are distributed three-dimensionally in the envelope. Indeed, each impactor impacted by the gearbox behaves as a point of virtual introduction of reducer positioned at the impactor. By arranging the impactors in a distributed manner, for example in a staggered manner, in the assembly according to the invention, the equivalent of a set comprising multiple injection points distributed in the section of the envelope of the invention is obtained. together. Preferably, the centroid of the orthogonal projections, on the outlet section of the elbow, the impactor zones impacted by the reducer is coincident with the center of gravity of said output section. This arrangement can make it possible to obtain a homogeneous and centered distribution of the reducer in the envelope. According to one embodiment, the injector is of the single jet type, each impactor intercepting a portion of the jet, the jet being totally intercepted by the impactors. This is an embodiment allowing the use of a simple type of injector, reliable and robust vis-à-vis the problem of fouling, because with a large injection port. The surface of the impactors facing the injector must, however, allow the interception of the entire jet.

According to another embodiment, the injector is of the multi-orifice type, and the jets from the different orifices are distributed between several impactors.

The number of impactors can be modulated according to the number of jets coming out of the injector. The inertia of the reducer jet allows it to impact the impactors in a manner substantially independent of the flow of exhaust gas leaving the engine, and therefore the operating point of the engine. [0023] Preferably, each jet is projected on a different impactor. Each jet is thus used to distribute the reducer in the assembly according to the invention, according to as many virtual points of introduction as there are jets.

Preferably, each impactor consists of a wafer disposed substantially orthogonally to the injector.

Preferably, the impactor pads are arranged in planes parallel to a median plane of the elbow. Thus, the impactors, in the form of platelets, have a small frontal surface generating a pressure drop vis-à-vis the exhaust gas flowing in the assembly according to the invention. Remarkably, this arrangement limits the frontal surface of the impactor both input and output of the elbow.

In a variant of the invention, a mixer is further disposed between the elbow and the catalyst for selective catalytic reduction of nitrogen oxides. This mixer, which ensures a perfect homogeneity of the mixture between the exhaust gas and the reducer, can be simple, and therefore a low cost, because the impactors have previously allowed to obtain a good distribution of the reducer in the exhaust stream. Preferably, the casing has a generally U-shaped shape. Thus, is the connecting duct between the two constituent branches of the "U" used to obtain a homogeneous mixture of the reducing agent in the gas? 'exhaust. The invention also relates to a motor vehicle having a space under the front engine cowling in which is disposed a combustion engine and an assembly according to the invention. The invention is described in more detail below and with reference to the figures schematically showing the system in its preferred embodiment. Figure 1 schematically shows a set of depollution angled "U" as envisaged in the state of the art. Figure 2 schematically shows a set of depollution bent in "U" according to a preferred embodiment of the invention. Figure 3 schematically shows a depollution set bent in "U" according to another preferred embodiment of the invention. Figure 1 shows schematically in section a set of exhaust gas treatment bent "U" as envisaged in the state of the prior art. Such an assembly has an envelope or "canning", comprising a first rectilinear branch 1 and a second rectilinear branch 2. The first branch 1 and the second branch 2 are intended to accommodate breads or monoliths of gas treatment. Straight prismatic exhaust, generally cylindrical. The monoliths may especially be: an oxidation catalyst 3, for the treatment of unburned hydrocarbons (HC) and carbon monoxide (CO); a catalyst for the selective catalytic reduction of nitrogen oxides or SCR 4 catalyst for the treatment of nitrogen oxides (NOX); a particulate filter for trapping and optionally the oxidation of the soot particles; a particulate filter carrying selective catalytic reduction impregnation of the nitrogen oxides, thus combining the functions of particulate filter and selective catalytic reduction catalyst of nitrogen oxides. Typically, the first branch 1 may contain an oxidation catalyst 3, and the second branch 2 may contain a catalyst SCR 4, of conventional type or being a particulate filter carrying a selective catalytic reduction impregnation of the oxides of nitrogen. The first branch comprises an inlet divergent 11. The second branch comprises a convergent outlet 21. The first and the second branch are connected by a fluidic connection 3, comprising at least one elbow 31. , and being such that the example shown here comprise a second bend 32 so as to give the assembly a substantially "U" shape. Although all of the figures presented herein are based on a "U" -based depollution architecture, the invention is applicable to any assembly having a bent envelope, and in particular to an "L" -shaped architecture in which the envelope has a single bend at about 90 °. Upstream of the SCR catalyst (or particulate filter catalyst SCR) is arranged means for introducing a SCR reducer (or a precursor of such an agent). This introduction means conventionally be an injector 5 whose nose leads into the set of depollution. As previously mentioned, it is necessary for the proper functioning of an SCR system to ensure a good mixture of the reducer in the exhaust gas prior to its arrival on the SCR catalyst. It is known to use to promote this mixture a device called mixer, interposed between the reducer injection point and the SCR catalyst, which aims to create turbulence in the exhaust gas. Thus, it is conventionally envisaged to integrate a mixer 6 in the second branch 2, just before the catalyst SCR 4. Thus arranged, the mixer limits the available volume in the second branch for the post-processing means. In Figure 2, there is shown schematically an assembly according to a first embodiment of the invention. In a single bent envelope, an oxidation catalyst 3 and a selective catalytic reduction catalyst for the nitrogen oxides 4 (which can be a particulate filter carrying a selective catalytic reduction impregnation of the oxides of carbon) are found. nitrogen). The envelope is bent between the oxidation catalyst 3 and the selective catalytic reduction catalyst of the nitrogen oxides 4. The mouth of a reducing injector 5 for the selective catalytic reduction of the nitrogen oxides arranged so as to injecting the reducer into the elbow 31. In the invention, the assembly further comprises one or more impactors 7 arranged in the bend so as to be impacted by the injected reducer and distribute it over the entire outlet section of the elbow. Typically, several impactors 7 are distributed in a staggered manner in the three dimensions. This distribution is shown in Figure 2. The figure on the right is a schematic sectional view of an assembly according to a preferred embodiment of the invention, wherein the envelope of the assembly has a general shape in " U ". The figure on the left corresponds to a schematic sectional view along the sectional plane A-A of the same set. In the right figure, we can see the distribution of the impactors in a first direction; in the figure on the left, we can see the distribution of the impactors according to the other two directions. Thus arranged, and associated with the use of an injector 5 having a nozzle with multiple jets, each of the jets impacting a different impactor, the system behaves substantially as if one multiplied the injection points in the set of post- treatment, with a virtual injection point at each impactor 7. This allows a good distribution of the gearbox at the outlet of the elbow 21. In particular, in the context of a U-shaped post-processing assembly architecture, the connection The fluidic fluid may advantageously have a flattened section, in which obtaining a homogeneous distribution of the reducer would be difficult to achieve with an injection of the reducer into a single point. Preferably and as in the embodiment shown here, the impactors 7 are formed of plates arranged in planes parallel to the median plane of the envelope. Thus, the plates are arranged so that the front surface of the impactor vis-à-vis the flow of exhaust gas in the assembly according to the invention is minimal, so as to limit the pressure losses generated by the impactors 7 The direction of the gaseous and reductant flows is shown schematically in all the figures by dashed arrows. It is understood that the use of impactor 7 in the form of platelets for distributing the reducing agent is particularly suitable for an angled architecture, the impactors being arranged in the elbow, as far as their orientation makes it possible not to generate loss of significant load both input and output of the elbow, because the frontal surface of the impactors is low both vis-à-vis the flow of gas entering the elbow 31 that the gases leaving the elbow. The substantially homogeneous distribution of the reducing agent over the entire outlet section of the bend is substantially independent of the flow of exhaust gas in the assembly. Indeed, by adopting a sufficient injection pressure of the reducer, the slight deflection of the reducer jets does not prevent the impact of these jets on the impactors 7. [0052] The elbow 31 is thus used to promote the mixing and / or decomposing the reducing agent (or its precursor) prior to entry into the SCR catalyst. In the variant of the invention shown in FIG. 3, a mixer 6 makes it possible to increase the turbulence and / or the travel distance of the exhaust gases between the outlet of the elbow and the inlet of the SCR catalyst, so as to promote the homogeneous mixture or the reducing agent or the decomposition of its precursor following the distribution, thanks to the impactors, of the element injected into the gas vein. The invention thus offers multiple advantages. The use of one or more impactors makes it possible: to obtain a homogeneous mixture in the exhaust gas treatment assembly, without generating a significant pressure drop; optimize the volume available for the post-processing monoliths in the second branch of an elbow assembly, the elbow being used to ensure the mixing of the reducer; to limit the fouling resulting from sub-compounds of a urea solution (used as reducing agent precursor), because the jet impacts parts (impactors) bathed in the gas flow of the exhaust gases (which is less favorable to fouling than ambient air); - to ensure the distribution and mixing function at a low cost; to ensure the distribution and mixing function independently of the flow of the exhaust gas as a whole, i.e. independently of the operating conditions of the engine producing the exhaust gas treated with all.

Claims (11)

1. A set of aftertreatment of the exhaust gas of a combustion engine, comprising, according to the flow direction of the exhaust gas, a selective catalytic reduction catalyst nitrogen oxides (4) disposed in an envelope bent downstream of a bend (31) of the casing, the assembly further comprising a reducing injector (5) for the selective catalytic reduction of the nitrogen oxides, arranged so as to inject the reductant into the elbow (31), characterized in that it further comprises one or more impactors (7) arranged to be impacted by all or part of the injected reducer so as to distribute it over the entire exit section of the elbow (31). ). 2. The assembly of claim 1, comprising several impactors (7) distributed three-dimensionally in the envelope. 3. The assembly of claim 2, wherein the barycentre orthogonal projections on the outlet section of the elbow, the areas of the impactor (7) impacted by the reducer is coincident with the center of gravity of said output section. 20 4. An assembly according to claim 2 or claim 3, wherein the injector (5) is of the single jet type, each impactor (7) intercepting a portion of the jet, the jet being completely intercepted by the impactors (7). 5. The assembly of claim 2 or claim 3 wherein the injector (5) is of the multi-orifice type, and wherein the jets from the various orifices are distributed between several impactors (7). 6. The assembly of claim 5, wherein each jet is projected on a different impactor (7). 7. An assembly according to any one of the preceding claims, wherein each impactor (7) consists of a wafer disposed substantially orthogonally jet impactant. 30 35 8. The assembly of claim 7, wherein the impactor plates (7) are disposed in planes parallel to a median plane of the bend. 9. An assembly according to any one of the preceding claims, wherein a mixer (6) is further disposed between the bend (31) and the catalyst catalytic selective reduction of nitrogen oxides (4). 10. Assembly according to one of the preceding claims, wherein the casing has a generally U-shaped. 11. Motor vehicle having a space under the engine bonnet in which is disposed a combustion engine and an assembly according to one of the preceding claims.